Chisato Miyahara scite author profile

Chisato Miyahara

5Publications

16Citation Statements Received

139Citation Statements Given

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133

Affiliations

Yamaguchi University

Publications

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Specification of Larval Axes of Partial Embryos in the Temnopleurid Temnopleurus toreumaticus and the Strongylocentroid Hemicentrotus pulcherrimus

et al. 2017

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Many sea urchins, including the strongylocentroid Hemicentrotus pulcherrimus, produce an amniotic cavity on the left for adult rudiment formation at the late larval stage. In contrast, temnopleurids form a cell mass at the early larval stage instead of an amniotic cavity. Although the mechanisms establishing left-right polarity of the amniotic cavity involve cell-cell interactions and signaling pathways, corresponding pathways for the cell mass are unknown. We analyzed the effects of blastomere isolation on the specification of larval axes in the temnopleurid Temnopleurus toreumaticus and compared them to those in H. pulcherrimus. Blastomere isolation at the two- or four-cell stages in T. toreumaticus disturbed the location of the cell mass and adult rudiment in approximately 10-20% of specimens. In contrast, isolation at the two-cell stage in H. pulcherrimus caused the left-right polarity to become random. When blastomeres isolated at the two-cell stage were cultured as pairs, approximately 20% of pairs had atypical polarity in both species. Following isolation at the four-cell stage, 71.4% of quartets produced larvae with atypical polarity in T. toreumaticus. Thus, cell-cell interaction between two daughter blastomeres after the second cleavage may be involved in the mechanism determining left-right polarity. Dye injection into a blastomere and subsequent observations indicated that the location of the boundary of the first cleavage showed similar patterns in both species. These observations suggest that species-specific mechanisms establish the larval axes and blastomeres at the two- and four-cell stages redistribute their cytoplasm, forming gradients that establish left-right polarity.

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Effects of Nodal inhibition on development of temnopleurid sea urchins

Kasahara¹,

Sakaguchi²,

Miyahara³

et al. 2018

Evolution and Development

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Adult rudiment formation in some temnopleurids begins with the formation of a cell mass that is pinched off the left ectoderm in early larval development. The cell mass forms the adult rudiment with the left coelomic pouch of the mesodermal region. However, details of the mechanisms to establish position of the cell mass are still unknown. We analyzed the inhibiting effect of Nodal, a factor for morphogenesis of the oral region and right side, for location of the cell mass, in four temnopleurids. Pulse inhibition, at least 5 min inhibition, during coelomic pouch formation allowed a cell mass to form on both sides, whereas treatments after that period did not. These results indicate that Nodal signaling controls the oral-aboral axis before gastrulation and then affects the position of the cell mass and adult rudiment up to coelomic pouch formation. They also indicate that the position of the adult rudiment under Nodal signaling pathways is conserved in temnopleurids, as adult rudiment formation is dependent on the cell mass.

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Author response for "Revealing the cells fated to form the cell mass in embryos of temnopleurid sea urchins"

Baba¹,

Miyahara²,

Yamanaka³

et al. 2022

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Author response for "Revealing the cells fated to form the cell mass in embryos of temnopleurid sea urchins"

Baba¹,

Miyahara²,

Yamanaka³

et al. 2021

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Revealing the cells fated to form the cell mass in embryos of temnopleurid sea urchins

et al. 2022

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Larvae of temnopleurid sea urchins form a cell mass (CM) instead of an amniotic cavity on the left side at the early developmental stage for formation of the adult rudiment. However, the cell lineage and the mechanisms that form the CM are still unknown. We analyzed the potential to form a CM in partial embryos resulting from microsurgeries, using two temnopleurid species, Mespilia globulus (L.) and Temnopleurus toreumaticus (Leske). CM formation was completed 28–34 h after fertilization at 24°C, corresponding to the period from the late prism to the two‐armed pluteus larval stages in both species. In the case of specimens dissected horizontally during the mesenchyme blastula to prism stages, the CM was formed in partial embryos containing enough of the an2 region, a part of the precursor cells that differentiate the ectoderm. The proportion of specimens with a CM was higher in T. toreumaticus than in M. globulus. Additionally, all larvae derived from half embryos obtained from dissection along the animal–vegetal axis at the mesenchyme blastula stage formed the CM. Transplantation of a stained animal or vegetal hemisphere at the 16‐cell stage into a nonstained vegetal or animal embryo indicated that the CM derives from the animal half. Exogastrulae vegetalized by lithium chloride treatment did not form the CM. These results indicate that the CM formation is dependent not only on the an2 region but also on signals from the vegetal region after the mesenchyme blastula stage.

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